Microfluidic device

ABSTRACT

A microfluidic device for separating a phase in a specimen has been described. This is based on a microfluidic trapping area, channels connected to it and integrated inputs and outputs connected onto the channels. An additional integrated input is provided which allows the flow in the device to be controlled and which may prevent leaking of the specimen and the phase.

FIELD OF THE INVENTION

The present invention relates to the field of separating liquid phases. More particularly, the present invention relates to microfluidic systems having a particular configuration for separating liquid phases, to be used for example for chromatography.

BACKGROUND OF THE INVENTION

Chemical reactor systems that make use of liquid propagation have a large number of applications, including production of chemical components, synthesis of nano-particles, separation and/or extraction of components, etc.

In separation techniques based on liquid propagation, use is typically made of the difference in affinity of various substances with a mobile phase and a stationary phase and/or of the difference in partition coefficients for partitioning of components. As each substance has its own “bonding power” to the stationary phase, they will be moved along faster or slower with the mobile phase and as such, certain substances can be separated from others. In principle, it is applicable to any composition, having the advantage that no evaporation of the material is required and that variations in temperature only have a negligible effect.

A specific example of a separation technique for separating mixtures is chromatography, for example in order to be able to analyse these accurately. A large variety of types of chromatography exists, such as gas chromatography, gel chromatography, thin-layer chromatography, adsorption chromatography, affinity chromatography, liquid chromatography, etc.

During liquid chromatography, a phase that is interesting for analysing is typically captured from the mixture first, to then be able to take it to a detector or inject it into an analysing column. Capturing the phase of interest typically happens in a trapping column, in which use is made of the difference in affinity of various substances with a mobile phase and a stationary phase and/or the difference in partition coefficients for partitioning of a mixture in its components.

As analysis often needs to happen on small quantities of specimen, it is important that when the specimen flows through the device, all useful parts of specimen are handled as efficiently as possible, and without loss. In a traditional device, the various components in the system, such as for example the trapping column and the analytical column, are typically coupled together using connectors and valves. Switching these valves then allows to control the liquid flow during the various actions such as loading of the specimen, separating of liquid phases of the specimen and injecting of the separated phase of interest to a detector or analytical column. However, due to their position in the specific configuration of devices in the state of the art, these valves and connectors often also have the disadvantage that a part of the specimen stays behind in dead volumes of or introduced by the valves. This may not only have a negative effect on the amount of specimen available but may also lead to contamination of the various separated phases, causing separation to happen less efficiently. In addition, in the traditional arrangement, these dead volumes introduce a significant plug broadening during the injection step causing the analytical separation to be negatively affected. The smaller the volumes used or worked in, the larger the impact will be.

In other words, there is room for improvement.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide good microfluidic systems and methods for separating liquid phases.

It is an advantage of embodiments of the present invention that a microfluidic device is provided whereby the various connectors are integrated at microfluidic level.

It is an advantage of embodiments of the present invention that the valves, used for controlling the liquid flow for various actions when using the device (loading the specimen, separating the phases, injecting the phase of interest), may be positioned in the configuration so that they generate only a minimal or even no dead volume for the specimen being studied.

It is an advantage of embodiments of the present invention that a microfluidic device is provided that may be connected into a valve circuit so that, during operation, it is not influenced by the volume of the connections and the valves.

It is an advantage of embodiments of the present invention that the chance of blockages in the connection circuit due to small particles, aggregates or macro-molecules accumulating, may be reduced or even prevented.

It is an advantage of embodiments of the present invention that the microfluidic device may be flowed through bidirectionally without risk of leaking of the stationary phase.

It is an advantage of embodiments of the present invention that the microfluidic device may be flowed through bidirectionally whereby the flow speed may be in the micro-litres per minute range as well as in the nano-litres per minute range.

It is an advantage of embodiments of the present invention that the microfluidic device filled with stationary phase may be flowed through via at least two inputs.

The above object may be achieved by a device according the present invention.

The present invention relates in one aspect to a microfluidic device for separating a phase in a specimen, the microfluidic device comprising a microfluidic trapping area for capturing the phase of interest, whereby the microfluidic trapping area is connected on two sides to a first duct and a second duct respectively, both integrated into the microfluidic device, and whereby the microfluidic device further

has a first integrated input connected to the first duct to take the specimen into the trapping area to separate the phase of interest,

has a first integrated output connected to the second duct, to discharge the rest of the specimen, once it has flowed through the trapping area

has a second integrated output connected to a selected duct selected from the first duct or the second duct, to elute the separated phase out of the device via this output,

has a second integrated input connected to a first duct or a second duct that is not the selected duct, to connect to a pump to be able to pump the separated phase out of the device, and

has a third integrated input, also connected to the selected duct via a connection located between the connection of the second integrated output on the selected duct and the microfluidic trapping area and via which the liquid flow during separating of the phase and eluting of the phase may be controlled.

It is an advantage that the phase, when eluting to the detector or the analytical column, no longer needs to pass a valve. It is an advantage of the invention that blockage due to accumulation of small particles (i.e. phase) in the device is avoided. It is an advantage of the invention that dead volumes which occur when using valves, are avoided. This is certainly relevant in the case of small volumes.

The third integrated input may, when the microfluidic device is in operation and during separating of the phase of interest, be configured to generate a counter-pressure in the selected duct so that no flow is possible to the second integrated output.

It is an advantage of embodiments of the present invention that leaking of the specimen to the analytical column during loading and separating may be prevented.

The third integrated input may, when the microfluidic device is in operation and during eluting of the phase of interest, be connected in a circuit with the first integrated input when the third integrated input is in the first duct or to the first integrated output when the third integrated input is in the second duct, thus preventing loss of sample via the first integrated input or via the first integrated output respectively during eluting.

The second integrated output may be connected to the first duct, and the microfluidic device may be configured so that, when in operation, the flow direction during separating and injecting is opposite. It is an advantage of the present invention that the microfluidic device allows bidirectional flow directions.

The second integrated output may be connected to the second duct, and the microfluidic device may be configured so that, when in operation, the flow direction during separating and eluting is the same.

The microfluidic device may have a fourth integrated input connected to the non-selected duct. Furthermore, the system may yet have additional inputs and/or outputs and further inputs may be provided to control the flow in the additional inputs and/or outputs.

The second integrated output may be configured to elute the separated phase via this output to a detector or an analytical column and the second integrated input may be connected to an analytical pump to be able to pump the separated phase to the detector or the analytical column.

At least the first and second integrated inputs may be adapted to connect to a pump system.

The linear flow velocity (S1, S2) may be controllable by the pump system.

The linear flow velocity (S1, S2) may be controllable by the pump system and by taking into account the intrinsic fluid characteristics of the device.

External connections for the inputs and outputs may be implemented by means of at least two six-way valves or valves with more than six ways.

External connections for the inputs and outputs may be implemented by means of at least one ten-way valve.

The device may be provided with a pillar structure, a monolithic phase or a packed material adapted to capture the phase.

The device may comprise a pump for loading the specimen via the first integrated input, may comprise a waste collector for collecting the specimen rest discharged via the first integrated output, may comprise a coupling to the analytical column for pumping the phase to the analytical column via the second integrated input.

The present invention also relates to a chromatography system, whereby the system comprises a microfluidic device as described above.

The present invention also relates to the use of a microfluidic device as described above as a stationary phase in a chromatography procedure.

The present invention further also relates to a method for operating a microfluidic device for separating a phase in a specimen as described above, the method comprising

trapping of a phase in the microfluidic trapping area by input via the first integrated input and an output via the first integrated output, whereby a counter-pressure is provided in the channel onto which the second integrated output is coupled to prevent eluting of the specimen, and eluting of the separated phase by pumping via the second integrated input to the second integrated output whereby loss of the separated phase via the first integrated input or the first integrated output is prevented by closing the first integrated input or the first integrated output in a circuit using the third integrated input.

It is an advantage of embodiments of the present invention that relaxation occurs in the transient pressure when switching from the separating phase to the eluting phase. Hereby, it is an advantage that the risk of loss of separated phase or disturbance of the system may be reduced.

The method may comprise controlling of a pump system connected to at least two inputs so that the device in operating mode is flowed through bidirectionally.

The method may comprise independently controlling of the speeds of the various flow directions (S1, S2).

Specific and preferable aspects of the invention have been included in the attached independent and dependent claims. Features of the dependent claims may be combined with features of the independent claims and with features of other dependent claims such as indicated and not only as expressly brought forward in the claims.

SHORT DESCRIPTION OF THE FIGURES

FIG. 1A and FIG. 1B show schematic representations of a microfluidic device with unidirectional or bidirectional flow respectively according to one embodiment of the present invention.

FIG. 1C shows a schematic representation of a microfluidic device in which an additional integrated input is provided, according to one embodiment of the present invention.

FIG. 2A to 2C illustrate a schematic representation of a first specific example of a microfluidic device using multiple-port valves according to one embodiment of the present invention, whereby FIG. 2A indicates the position of the valves during loading of the specimen, FIG. 2B indicates the position of the valves during separating of the stages and FIG. 2C indicates the position of the valves when injecting to a detector or into an analytical column.

FIG. 3A to 3C illustrate a schematic representation of a second specific example of a microfluidic device using multiple-port valves according to one embodiment of the present invention, whereby FIG. 3A indicates the position of the valves during loading of the specimen, FIG. 3B indicates the position of the valves during separating of the stages and FIG. 3C indicates the position of the valves when injecting to a detector or into an analytical column.

FIG. 4A to 4C illustrate a schematic representation of a third specific example of a microfluidic device using multiple-port valves according to one embodiment of the present invention, whereby FIG. 4A indicates the position of the valves during loading of the specimen, FIG. 4B indicates the position of the valves during separating of the stages and FIG. 4C indicates the position of the valves when injecting to a detector or into an analytical column.

The figures are only schematic and not restrictive. The dimensions of some components may be exaggerated and are not represented to scale in the figures for illustrative purposes. Reference numbers used in the claims cannot be interpreted to restrict the scope of protection. In the various figures, the same reference numbers refer to the same or analogous elements.

DETAILED DESCRIPTION OF THE EMBODIMENTS

The present invention will be described in respect of specific embodiments and with reference to certain drawings, however the invention will not be restricted thereto but will only be limited by the claims.

Reference throughout this specification to “one embodiment” or “an embodiment” means that a specific feature, structure or characteristic described in connection with the embodiment has been included in at least one embodiment of the present invention. So, occurrence of the expressions “in one embodiment” or “in an embodiment” in various locations throughout this specification do not necessarily all need to refer to the same embodiment all the time, but may do so. Furthermore, the specific features, structures or characteristics may be combined in any suitable manner as would be clear to a person skilled in the art on the basis of this publication, in one or several embodiments.

Similarly, it should be appreciated that in the description of sample embodiments of the invention, various features of the invention are sometimes grouped together in one single embodiment, figure or description thereof intended to streamline the publication and to help the understanding of one or several of the various inventive aspects. This method of publication should therefore not be interpreted as a reflection of an intention that the invention requires more features than explicitly mentioned in each claim. Rather, as the following claims reflect, inventive aspects lie in fewer than all features of one single previously disclosed embodiment. So, the claims following the detailed description have been explicitly included in this detailed description, with every independent claim being a separate embodiment of the invention.

Furthermore, while some embodiments described herein contain some, but not other, features included in other embodiments, combinations of features from various embodiments are intended to be within the scope of the invention, and form these various embodiments as would be understood by the person skilled in the art. For example, in the following claims, any of the embodiments described may be used in any combination.

Furthermore, the terms first, second, third and the like in the description and in the claims are used to distinguish similar elements and are not necessarily used for describing an order, nor in time, nor in space, nor in ranking nor in any other manner. It should be understood that the terms used in this way are interchangeable in appropriate circumstances and that the embodiments of the invention described are suitable to work in a different order than described or indicated here.

Furthermore, the terms top, bottom, above, in front of and the like used in the description and the claims are used for description purposes and not necessarily to describe relative positions. It should be understood that the terms used as such are interchangeable in given circumstances and that the embodiments of the invention described herein are also suitable for functioning according to different orientations than described or indicated here.

It should be noted that the term “comprises”, as used in the claims, should not be interpreted as being restricted to the items described thereafter; this term does not exclude any other elements or steps. It may be interpreted as specifying the presence of the features, values, steps or components indicated which are referred to but does not exclude the presence or addition of one or several other features, values, steps or components, or groups thereof. So, the extent of the expression “a device comprising items A and B” should not be restricted to devices consisting of components A and B only. It means that in respect of the present invention, A and B are the only relevant components of the device.

In the description provided here, a large number of specific details are disclosed. It may therefore be understood that embodiments of the invention may be embodied without these specific details. In other cases, well-known methods, structures and techniques are not shown in detail in order to keep this description clear.

Where in the present invention, reference is made to “integrated duct”, “integrated input” or “integrated output”, reference is made to a heterogeneous built-in duct, built-in input or built-in output in a monolithic microfluidic carrier, for example chip, on which the device is provided. Where in the present invention reference is made to a pump, reference is not only made to a hydraulic pump, but alternatively an array of pumps may be used such as for example pressure-driven pumps, peristaltic pumps, electro-osmotic pumps, piezoelectric pumps, injection pumps, etc.

Where in the present invention, reference is made to separating a phase, reference may also be made to capturing a phase or purifying a phase or splitting a specimen into two or more phases.

Where in the present invention, reference is made to eluting a phase, reference may also be made to mobilising a phase, usually to remove it from the device.

The present invention relates to a microfluidic device for separating liquid phases. Reference may also be made to such a microfluidic device as a microfluidic trapping column. Separating of phases may be very advantageously used in the framework of liquid chromatography, although the invention is not restricted by this. According to embodiments of the present invention, a microfluidic device is described comprising a microfluidic trapping area for capturing the phase of interest. Hereby, it is an advantage of embodiments that a solution is provided whereby no valves need to be introduced at chip level, but that a simple solution is provided to provide a compact device for separating stages wherein no detrimental effects occur caused by dead volume in the system. Furthermore, with this simple solution, all functionality is still obtained for separating and subsequently eluting the phase.

In embodiments of the present invention, the microfluidic trapping area is on two sides, for example sides opposite each other, connected to a first duct and a second duct respectively, both integrated into the microfluidic device. The microfluidic device further comprises a first integrated input connected to the first duct, to take the specimen into the trapping area in which the phase of interest will be separated. It also comprises the first integrated output connected to the second duct, to discharge the rest of the specimen, after it has passed through the microfluidic trapping area and the phase of interest has immobilised.

The microfluidic device also comprises a second integrated output connected to a selected duct selected from the first duct or the second duct, to elute the separated phase from the device via this output, and a second integrated input connected to the first duct or the second duct that is not the selected duct, to connect to a pump to be able to pump the separated phase out of the device.

In addition, the microfluidic device also comprises a third integrated input, also connected to the selected duct via a connection located between the connection of the second integrated output on the selected duct and the microfluidic trapping area and via which the liquid flow during separating of the phase and eluting of the phase may be controlled.

As will be shown, the column for separating and eluting may be based on a unidirectional flow direction or on a bidirectional flow direction, i.e. whereby different (opposing) flow directions are used when separating the phase and eluting the separated phase.

Further characteristics and advantages of embodiments of the present invention will be described with reference to the figures. It should be noted here that the invention is not restricted to the specific embodiments shown in these figures or described in the examples, but is only limited by the claims.

FIG. 1A shows a schematic representation of a microfluidic device 100 according to one embodiment of the present invention for separating a phase in a specimen. The microfluidic device comprises a microfluidic trapping area 110 for capturing the phase of interest. This microfluidic trapping area 110 may for example comprise a pillar structure, monolithic phase or packed material adapted to capture the phase of interest, as illustrated in FIG. 1A, but the present invention is not limited thereto. Trapping area 110 may typically have dimensions in the range of 1 mm to 50 mm in length, 0.1 mm to 50 mm in width and 1 μm to 2 mm in depth. Microfluidic trapping area 110 is integrated into a microfluidic chip that comprises the device or a large part thereof. Microfluidic device 100 is connected on two sides to respectively a first duct 120 and a second duct 130, both integrated in microfluidic device 100. A typical diameter of the first duct and/or the second duct is in the 10 μm to 500 μm range, or in the case of a square intersection, a width of 10 μm to 500 μm and a depth of 0.5 μm to 5000 μm (5 mm). Microfluidic device 100 shown in FIG. 1A further has a first integrated input I1, connected to first duct 120 and a first integrated output U1, connected to the second duct. Via this input and output, the specimen may be introduced into the trapping area to separate the phase of interest. While the phase of interest is immobilised into trapping area 110, the rest of the specimen is discharged. This may be to a rest container for example, although further handling, processing or treating of this part of the specimen still remain possible. Furthermore, microfluidic device 100 further comprises a second integrated output U2, connected to second duct 130, to elute the separated phase via this output. This eluting may comprise transporting of the separated phase to a detector, injecting of the separated phase into an analytical column, etc. (not shown in the figure). Microfluidic device 100 from FIG. 1A further typically comprises a second integrated input I2, connected to first duct 120, with which the phase to be eluted may be pumped. Second integrated input I2 may be connected or is connected to a pump (not shown in the figure) to be able to pump the separated phase out of the device, via second integrated output U2. This eluting may for example happen to a detector or to an analytical column. The flow direction for a device as shown in FIG. 1A is the same for separating and eluting, so that reference may be made to a device with unidirectional flow.

Furthermore, microfluidic device 100 from FIG. 1A comprises a third integrated input I3, which in addition to integrated output U2 is also connected to second duct 130. Third integrated input I3 is located between the connection of second integrated output U2 on two-duct 130 and microfluidic trapping area 110.

Microfluidic device 100 from FIG. 1A operates as follows: a specimen of which a phase of interest is to be separated or isolated, is taken to first integrated input I1. As this is connected to first duct 120, the specimen is taken to microfluidic trapping area 110. Here the phase of interest is separated. The rest of the specimen, without the separated phase, is then removed from microfluidic trapping area 110 via first integrated output U1. It is an advantage of embodiments of the invention that when loading and separating the specimen, no loss of specimen can occur via second integrated output U2. This is made impossible by the use of third integrated input I3, which during loading of the specimen and separating of the phase, is connected to a pump and generates counter-pressure in second duct 130 and so makes flow to second integrated output U2 impossible. As such, leaking of the specimen, for example to the detector or analytical column, is prevented, without using a physical shut-off valve in the microfluidic substrate. Once the rests of the separated specimen have been discharged via first integrated output U1, the phase that was captured or separated in microfluidic trapping area 110 will be pumped out of trapping area 110 via integrated output U2 by pumping via second integrated input I2, which on one side is connected to an analytical pump and on the other side is connected to first duct 120. Again, using third integrated input I3, the liquid flow is prevented from escaping via a parasite duct. More specifically is prevented, by connecting third integrated input I3 to the first integrated output in a circuit, that the separated phase would exit the device via the first integrated output instead of via the second integrated output. Particularly considering the often small quantity of the separated phase, it is important not to have any losses.

So the liquid flow may be controlled via third integrated input I3 during separating of the phase and injecting of the phase.

FIG. 1B shows a schematic representation of a microfluidic device 100 according to an alternative embodiment of the present invention. The difference with the microfluidic device shown in FIG. 1A is that the system is configured for bidirectional flow, whereby the flow directions in separating and eluting are therefore opposite. This microfluidic device 100 therefore comprises analogous components as described for the embodiment shown in FIG. 1A. In FIG. 1B, second integrated output U2 is however connected to first duct 120, instead of to the second duct. As a result, the corresponding integrated input is connected to second duct 130. This way, eluting of the captured phase may happen in opposing sense of flow compared with the sense of flow for loading the specimen. Here too, microfluidic device 100 from FIG. 1B comprises a third integrated input I3, which in addition to integrated output U2 is also connected to first duct 130. Third integrated input I3 is located between the connection of second integrated output U2 on first duct 130 and microfluidic trapping area 110.

Microfluidic device 100 from FIG. 1B operates as follows: a specimen of which a phase of interest is to be separated, is taken to first integrated input I1. As this is connected to first duct 120, the specimen is taken to microfluidic trapping area 110. Here the phase of interest is separated. The rest of the specimen, without the separated phase of interest, is then removed from microfluidic trapping area 110 via first integrated output U1. By generating a pressure via third integrated input I3 is prevented that the specimen flows via second integrated output U2 instead of the trapping area. Once the rests of the separated specimen have been discharged via first integrated output U1, the phase that was captured or separated in microfluidic trapping area 110 will be pumped out of trapping area 110 via second integrated input I2, which is connected to an analytical pump and is connected to second duct 130. By connecting third integrated input I3 to first integrated input I1 in a circuit, loss via first integrated input I1 is prevented when eluting. So the liquid flow may be controlled here too via third integrated input I3 during separating of the phase and injecting of the phase.

Microfluidic devices 100 from FIGS. 1A and 1B do not make use of integrated valves. Furthermore, as the input and output elements are integrated, they ensure compact microfluidic devices. Although valves are used to make the various connections, for example from inputs to the pump or for creating a circuit between inputs and/or outputs among each other, the specific configuration of the device together with the fact that the valves are external to the device and not in the direct path of elution of the phase before it, ensures that there is no dead volume and so no loss of separated phase, nor associated dispersion of the eluted plug. In other words, a compact device for accurately separating a phase is achieved.

As an example, microfluidic device 100 from FIG. 1C is further also shown. Herein a further additional integrated access is provided. This may for example allow to prevent loss of specimen to the second integrated input by generating, when loading the specimen, a pressure in the first duct between the first and the second integrated accesses. More generally it should be noted that the device according to embodiments of the present invention, in addition to the inputs and outputs shown, other additional inputs and outputs may be provided and that, according to the idea of the further third integrated input in the preceding examples, there may be further inputs to control the flow in the other additional inputs and outputs.

As a further illustration, not restricting embodiments hereto, schematic representations of microfluidic devices according to specific implementations of exemplary embodiments are shown in the following figures. Examples are given whereby use is made of external six-way valves and/or ten-way valves. It should be noted that these are just some examples, whereby these external valves may of course be implemented differently, whereby a six-way valve may for example be replaced by two correctly configured three-way valves.

In a first explicit implementation, a microfluidic device is shown which makes use of two six-port valves and one ten-port valve. FIG. 2A to FIG. 2C schematically illustrate the configurations for the valves and the associated configuration of the microfluidic device for loading the specimen, separating and eluting respectively. Microfluidic device 100 is coupled to a first six-port valve for injection 210, a second six-port valve for column 220 and a ten-port valve for column 230. Various positions of the multi-port valves result in various interconnections of the ports so that various configurations may be implemented between the inputs and outputs of the device between them and/or of these inputs and outputs and pumps.

FIG. 2A indicates the position of the valves during loading of the specimen. Here, loading of the specimen happens in one of six-port valves 210, separately from the device. The specimen is taken into the valve in injection loop 240, so that, afterwards, it may efficiently be introduced into the device for separating. For this, use is made of injection needle 242 for example and a further injection valve 244, although other means are possible too.

The embodiment described in FIG. 2A operates as follows to load a specimen: the specimen is injected via port 6 into first multi-port valve 210 by making use of an injection needle 242. The specimen then flows away through the path between valves 5, 6, 3, 4 and will be loaded into injection loop 240.

Once the specimen is loaded into injection loop 240, the first, second and third multi-port valves will be adjusted, manually or automatically, so that the specimen may be taken to inside trapping area 110 and the phase of interest may be separated. FIG. 2B illustrates the position of the valves during separating of the phase. In this phase, injection loop 240 is connected to a loading pump 250 and, via ports on the ten-way valve, to trapping area 110. To a second side, trapping area 110 is connected to other ports of ten-port valve 230. As such, a path is formed between first pump 250, e.g. the loading pump, injection loop 240 and trapping area 110 allowing the specimen to flow to trapping area 110 using the loading pump. Furthermore, a further path is formed from the first output of the trapping area to output duct 270. The ports of the third multi-port valve provide the connection to the third integrated input, which ensures that the specimen does not pass to analytical column 140 which is already also connected to trapping area 110. For this, port 1 of the third multi-port valve is connected to a pump or pressure valve or pressure tank 280 and on the other side connected to the third integrated input via port 6. It should be noted that analytical column 140 may also be integrated in the same microfluidic substrate as the trapping area. Analytical column 140 may then also be permanently connected to trapping area 110.

The embodiment described in FIG. 2B operates as follows to separate a specimen: the specimen that is in injection loop 240 is taken to the first duct by loading pump 250. When the specimen is pumped to the entrance or the first duct, the pump, pressure valve or pressure tank 280 connected to the third integrated input in a pressure generation in the first duct foresees that the specimen cannot flow to the detector or analytical column 140. After the specimen has passed through trapping area 110 and its phase has therefore been separated, the waste or rests of the specimen are discharged via the path formed by the connection between the second duct and the second multi-port valve. The configuration ensures a zero-dead-volume connection with active anti-blockage action between trapping area 110 and analytical column 140.

Now the phase is separated, this phase must typically be taken out of the device, for example to a detector or an analytical column. For this, liquid will be injected into the trapping area, the separated phase will be mobilised and passed to the detector or analytical column. FIG. 2C shows the position of the valves when eluting, for example to a detector or an analytical column. For this, a pump 260, called micro-pump or analytical pump in the example, is connected to the second duct and to trapping area 110 via ten-point-valve 230. The separated phase will then be mobilised to trapping area 110 and taken to analytical column 140 via the second integrated output (in the current example). The other inputs and outputs are coupled to a stop via remaining ports on the ten-port valve and the six-port valve so no flow is possible and no phase can leak into these ducts. Loading pump 250 is connected to a rest-output 252

FIG. 3A to 3C illustrate a schematic representation of a second specific example of a microfluidic device using three six-port valves. In this example, loading and separating happens similarly as described in the first explicit example. During eluting, shown in FIG. 3C, however, instead of making use of stops, the first integrated input and the third integrated input are connected together in a circuit via one of the six-port valves, so that no flow is possible here either. This also results in the fact that no phase can leak.

FIG. 4A to 4C illustrate a schematic representation of a third specific example of a microfluidic device using one six-way valve and one ten-way valve. The various ports are optimally configured here to get a same effective configuration as described in the second specific example.

In a second aspect, the present invention also relates to a chromatography system comprising a device as described in the first aspect and an analytical column connected to the device and via which a specific phase from the specimen may be injected into the analytical column. Further components of the chromatography system may be as in chromatography systems known in the state of the art. Characteristics and advantages of the current chromatography system correspond with the characteristics and advantages provided in the description of embodiments of the microfluidic device from the first aspect.

In a third aspect, the present invention also relates to the use of a microfluidic device according to one of the embodiments from the first aspect as a stationary phase in a chromatography procedure.

In a fourth aspect, the present invention relates to a method for operating a microfluidic device for separating a phase in a specimen. The microfluidic device corresponds thereby with a microfluidic device as described in embodiments from the first aspect. The method comprises trapping of a phase in the microfluidic trapping area by input via the first integrated input and an output via the first integrated output, whereby a counter-pressure is provided in the channel onto which the second integrated output (U2) is coupled to prevent eluting of the specimen. The method also comprises eluting of the separated phase by pumping via the second integrated input and to the second integrated output whereby loss of the separated phase via the first integrated input or the first integrated output is prevented by closing the first integrated input or the first integrated output in a circuit using the third integrated input. The method may also comprise controlling of a pump system connected to at least two inputs so that the device in operating mode is flowed through bidirectionally. The speeds of the flow in the various flow directions may also be controlled. Further method steps may correspond with the functionality of the various characteristics of the device as described in the first aspect.

The preceding description gives details of certain embodiments of the invention. It will, however, be clear that no matter how detailed the above turns out to be in text, the invention may be applied in many ways. It should be noted that the use of certain terminology when describing certain characteristics or aspects of the invention should not be interpreted as implying that the terminology herein is defined again to be restricted to specific characteristics or aspects of the invention to which this terminology is coupled.

REFERENCES

-   -   100 microfluidic device     -   110 microfluidic trapping area     -   120 first duct     -   130 second duct     -   140 detector or analytical column     -   210 six-port valve for injection     -   220 six-port valve for the column     -   230 ten-port valve for the column     -   240 injection loop     -   242 injection needle     -   244 injection valve     -   250 loading pump     -   252 rest     -   260 micro-pump     -   270 rest     -   280 pressure tank     -   290 zero-dead-volume connection with active anti-blockage     -   I1 integrated first input     -   I2 integrated second input     -   I3 integrated third input     -   I4 integrated fourth input     -   U1 integrated first output     -   U2 integrated second output 

The invention claimed is:
 1. A microfluidic device for separating a phase in a specimen, the microfluidic device comprising a microfluidic trapping area for capturing a phase of interest, whereby the microfluidic trapping area is connected on two sides to a first duct and a second duct respectively, both integrated in the microfluidic device, and whereby the microfluidic device further comprising: a first integrated input connected to the first duct to take the specimen into the microfluidic trapping area to separate the phase of interest; a first integrated output connected to the second duct to discharge the rest of the specimen, once it has flowed through the microfluidic trapping area; a second integrated output connected to a selected duct selected from the first duct or the second duct, to elute the separated phase of interest out of the microfluidic device via this output; a second integrated input connected to the first duct or the second duct that is not the selected duct, to connect to a pump to be able to pump the separated phase of interest out of the microfluidic device; and a third integrated input, also connected to the selected duct via a connection located between the connection of the second integrated output on the selected duct and the microfluidic trapping area and via which a liquid flow during separating of the phase of interest and eluting of the phase of interest may be controlled; wherein the third integrated input, when the microfluidic device is in operation and during eluting of the phase of interest, is connected in a circuit to the first integrated input when the third integrated input is in the first duct or to the first integrated output when the third integrated input is in the second duct, thus preventing loss of specimen via the first integrated input or via the first integrated output respectively during eluting.
 2. The microfluidic device according to claim 1, whereby the third integrated input, when the microfluidic device is operating and during separating of the phase of interest, is configured to generate a counter-pressure in the selected duct and no flow is possible to the second integrated output.
 3. The microfluidic device according to claim 1, whereby the second integrated output is connected to the first duct, and the microfluidic device is configured so that, when it is operating, a flow direction is opposite during separating and injecting.
 4. The microfluidic device according to claim 1, whereby the second integrated output is connected to the second duct, and the microfluidic device is configured so that, when it is operating, a flow direction is the same during separating and eluting.
 5. The microfluidic device according to claim 1, wherein the microfluidic device has connected a fourth integrated input to the non-selected duct.
 6. The microfluidic device according to claim 1, in which the second integrated output is configured to elute the separated phase via this output to a detector or an analytical column and the second integrated input is connected to a pump to be able to pump the separated phase to the detector or the analytical column.
 7. The microfluidic device according to claim 1, whereby at least the first and the second integrated inputs are adapted to connect to a pump system.
 8. The microfluidic device according to claim 1, whereby external inputs and outputs are implemented by at least two six-way valves or valves with more than six ways.
 9. The microfluidic device according to claim 1, whereby external connections to the inputs and outputs are implemented using at least one ten-way valve.
 10. The microfluidic device according to claim 1, whereby the microfluidic device is provided with a pillar structure, a monolithic phase, a packed material, adapted to capture the phase of interest.
 11. The microfluidic device according to claim 1, whereby the device comprises a pump for loading the specimen via the first integrated input, comprises a waste collector for collecting the specimen rest discharged via the first integrated output, a coupling to the analytical column on the two integrated output, an analytical pump for pumping the phase of interest to the analytical column via the second integrated input.
 12. The microfluidic device according to claim 1, whereby an analytical column is integrated into the same microfluidic substrate as the microfluidic trapping area.
 13. A chromatography system, whereby the system comprises a microfluidic device according to claim
 1. 14. Use of a microfluidic device according to claim 1 as a stationary phase in chromatography procedure.
 15. The microfluidic device according to claim 1, whereby a linear flow velocity is controllable by the pump system.
 16. The microfluidic device according to claim 15, whereby the linear flow velocity is controllable by the pump system and by taking into account the intrinsic fluid characteristics of the device.
 17. A method for operating a microfluidic device for separating a phase in a specimen according to claim 1, the method comprising: trapping of a phase in the microfluidic trapping area by input via the first integrated input and an output via the first integrated output, whereby a counter-pressure is provided in the channel onto which the second integrated output is coupled to prevent eluting of the specimen, and eluting of the separated phase by pumping via the second integrated input and to the second integrated output whereby loss of the separated phase via the first integrated input or the first integrated output is prevented by closing the first integrated input or the first integrated output in a circuit using the third integrated input, while the third integrated input is connected in a circuit to the first integrated input when the third integrated input is in the first duct or to the first integrated output when the third integrated input is in the second duct, thus preventing loss of specimen via the first integrated input or via the first integrated output respectively during eluting.
 18. A method for operating a microfluidic device according to claim 17, the method comprising controlling of a pump system connected to at least two inputs so that the microfluidic device allows a bi-directional flow through the microfluidic device in an operating mode.
 19. A method according to claim 18, the method comprising independently controlling of the various linear flow velocities. 